JP6931422B2 - Through-actuated puncture of radial wall - Google Patents

Description

(Cross-reference of related applications)
The present application claims the priority benefit of US Provisional Application No. 62 / 530,080, filed July 7, 2017, which is incorporated herein by reference in its entirety.

(background)
A sheet metal ring with a hole in the side wall is typically produced by punching a hole in the sheet metal and then bending the sheet metal to form a ring. In such a system, the sheet metal can be passed through a hole punching machine, which uses a single punching machine to continuously punch each individual hole.

(wrap up)
In one embodiment, the thru-actuated stamping station has an expandable core configured to apply radial outward pressure to the radially inwardly facing surface of the radial wall and a radial. Includes at least one through-actuated punching machine for piercing individual holes in the radial wall along the inward direction.

In one embodiment, the method for puncturing a radial wall is at the same time (a) applying a radial outward pressure to a surface that faces inwardly in the radial direction of the radial wall. (B) It involves driving a thru, operating at least one punching machine, and piercing at least one hole in a radial wall along a direction opposite to the outward pressure in the radial direction.

In one embodiment, the method for forming an object with a radial wall with a hole is to form a ring with a radial wall and within the radial wall using at least one through-actuated punching machine. Includes puncturing at least one hole.
The present specification also provides, for example, the following items.
(Item 1)
It is a through-actuated stamping station
With an expandable core configured to apply radial outward pressure to the surface of the radial wall facing inward in the radial direction.
With at least one through-actuated punching machine for puncturing individual holes in the radial wall along the radial inward direction.
A stamping station equipped with.
(Item 2)
With the drive ring
A punching machine holder and a punching machine holder, each of which connects one or more of the at least one through-actuated punching machine to the drive ring.
A guide for guiding each punching machine holder toward the radial wall, and
With a first thru for rotating the drive ring to drive each puncher holder along the guide so as to puncture the radial wall with each thru actuated puncher.
The stamping station according to item 1, further comprising.
(Item 3)
The stamping station according to item 2, wherein one or more of the at least one punching machine holder strictly has one punching machine mounted on the punching machine holder.
(Item 4)
The stamping station according to item 2, wherein one or more of the at least one punching machine holder has more than one punching machine mounted on the punching machine holder.
(Item 5)
Each punching machine holder is
A punching machine body having one or more of the individual one or more of the at least one through-acting punching machine attached thereto, wherein the guide is configured to guide the punching machine body. When,
A lever that connects the punching machine main body to the drive ring, and the lever (a) with respect to the punching machine main body so that the rotation of the drive ring moves the punching machine main body along the guide. To the drive ring via a proximal joint that allows the lever to pivot, and (b) a distal joint that allows the lever to pivot with respect to the drive ring. With the lever to be combined
2. The stamping station according to item 2.
(Item 6)
5. The item 5. The punching machine holder is configured to install the individual punching machine body in the most inward position in the radial direction when the lever is parallel to the punching machine body. Stamping station.
(Item 7)
The stamping station of item 2, further comprising a second thru for cooperating with the first thru to rotate the drive ring.
(Item 8)
7. The stamping station of item 7, wherein the first thru and the second thru are coupled to both sides of the drive ring.
(Item 9)
Further provided with a tapered plunger capable of moving along the axial dimensions of the radial wall.
The expandable core is moved so that the tapered plunger is interfacially contacted with the tapered die compartment at a larger diameter of the tapered plunger so that the tapered die compartment is radially outwardly outward. The stamping station of item 1, comprising a plurality of tapered die compartments arranged around the tapered plunger so as to move.
(Item 10)
The plurality of tapered die compartments are such that when the tapered plunger pushes the tapered die compartment outward in the radial direction, the tapered die compartment faces the surface facing inward in the radial direction of the radial wall. 9. The stamping station of item 9, comprising a plurality of individual radial outward facing surfaces for applying pressure.
(Item 11)
The surface of the tapered die compartment facing outward in the radial direction has the radius so that when the tapered die compartment applies outward pressure in the radial direction, the final shape of the radial wall is achieved. The stamping station according to item 10, which approximates the final shape of a surface facing inward in the radial direction of the directional wall.
(Item 12)
The stamping station according to item 11, wherein the final shape is cylindrical or conical.
(Item 13)
The stamping station of item 11, wherein the final shape is characterized by a circular cross section at any axial position within the axial range of the radial wall.
(Item 14)
9. The stamping station of item 9, wherein the tapered die compartment forms one or more shoots configured to receive and drop material removed from the radial wall by the puncture.
(Item 15)
The stamping station according to item 1, wherein the at least one through-actuated punching machine includes a plurality of rectangular punching machines for puncturing individual rectangular holes in the radial wall.
(Item 16)
The item 1. Stamping station.
(Item 17)
After puncturing the radial wall in the thru-actuated stamping station, the second expandable core for holding the radial wall is the radial direction. With a second expandable core configured to apply radial outward pressure to the inwardly facing surface.
To puncture at least one individual second hole in the radial wall or reshape one or more of the at least one first hole along a radial inward direction. With at least one second through-actuated punching machine
The stamping station according to item 1, wherein the stamping station is implemented in a stamping system further comprising a second through-actuated stamping station.
(Item 18)
A method for puncturing a radial wall, and at the same time
Applying an outward pressure in the radial direction to the surface of the radial wall facing inward in the radial direction and
To drive the thru, activate at least one punching machine, and puncture at least one hole in the radial wall along the direction opposite to the radial outward pressure.
Including methods.
(Item 19)
The method of item 18, wherein the applying step comprises expanding the core and applying an outward pressure in the radial direction.
(Item 20)
19. The method of item 19, wherein the expanding step uses a tapered plunger to push a plurality of tapered die compartments located inside the radial wall outward in the radial direction.
(Item 21)
The method of item 18, wherein the applying step comprises achieving the final shape of the surface facing inward in the radial direction.
(Item 22)
21. The method of item 21, wherein the applied step further comprises preventing at least one of (a) burrs in the radial wall and (b) deformation of the radial wall.
(Item 23)
21. The method of item 21, wherein the step to be achieved comprises achieving that the surface facing inward in the radial direction has a circular cross section at any axial position of the radial wall.
(Item 24)
21. The method of item 21, wherein the steps to be achieved include achieving that the surface facing inward in the radial direction is cylindrical or conical.
(Item 25)
The driving step
Driving the thru to move each punching machine and rotating the thru and the drive ring coupled to each punching machine.
To guide the movement of each punching machine along the radial inward direction and puncture the radial wall.
18. The method of item 18.
(Item 26)
The driving step
Moving a plurality of punching machines coupled to the drive ring
To guide each of the punching machines along individual radial inward directions to puncture a plurality of holes in the radial wall.
25. The method of item 25.
(Item 27)
In the driving step, directionally shifting the position of each distal end of at least one lever coupled to the driving ring.
In the guiding step, (a) one or more of the at least one punching machine connected to, and (b) mounted on an individual proximal end of the at least one lever. Inducing inward movement in each radial direction of at least one punching machine body having an individual to puncture the at least one hole.
25. The method of item 25.
(Item 28)
Performing the application and driving steps within the first stamping station to puncture at least one hole in the radial wall.
Performing the application and driving steps within the second stamping station to puncture at least one second hole in the radial wall, or one or more of the at least one first hole. To change the shape
18. The method of item 18.
(Item 29)
A method for forming an object with a radial wall with holes,
Forming a ring with a radial wall and
To puncture at least one hole in the radial wall using at least one through-actuated punching machine.
Including methods.
(Item 30)
29. The method of item 29, further comprising modifying the shape of the ring after the puncturing step.
(Item 31)
30. The method of item 30, wherein the modifying step comprises forming the ring into a roll.
(Item 32)
The puncturing step is
Applying an outward pressure in the radial direction to the surface of the radial wall facing inward in the radial direction and
To drive the thru, activate at least one punching machine, and puncture at least one hole in the radial wall along the direction opposite to the radial outward pressure.
29. The method of item 29.
(Item 33)
32. The method of item 32, wherein the applying step comprises achieving the final shape of the radial wall.
(Item 34)
33. The method of item 33, wherein the applied step further comprises preventing at least one of (a) burrs in the radial wall and (b) deformation of the radial wall.
(Item 35)
29. The method of item 29, wherein the forming step comprises forming a flat sheet into a ring in a roll.
(Item 36)
The roll-shaped step further comprises forming a plurality of compartments in the ring along the axial dimensions of the ring, with at least two of the compartments on the axis of the ring. 35. The method of item 35, which has different polar angles with respect to each other.
(Item 37)
29. The method of item 29, wherein the forming step comprises cutting the ring from a tube.
(Item 38)
29. The method of item 29, wherein the forming step comprises forming the ring such that the radial wall is cylindrical or conical.
(Item 39)
29. The method of item 29, wherein the forming step comprises forming the ring such that the cross section of the radial wall at any axial position is circular.

FIG. 1 illustrates a thru-actuated stamping station according to an embodiment. 2A and 2B illustrate expandable cores, including multiple die compartments, according to certain embodiments. 3A and 3B illustrate one embodiment of the thru-actuated stamping station of FIG. FIG. 4 illustrates two examples of through-actuated stamping stations mounted within a stamping system according to an embodiment. FIG. 5 is a top view of the stamping station of FIG. 6 and 7 show the stamping stations of FIGS. 4 and 5 in more detail. 6 and 7 show the stamping stations of FIGS. 4 and 5 in more detail. FIG. 8 illustrates a punching machine assembly having a single punching machine according to an embodiment. FIG. 9 illustrates a punching machine assembly having two punching machines according to an embodiment. FIG. 10 illustrates an expandable core, including a plurality of die compartments, according to an embodiment. 11 and 12 illustrate a stamping station 1100 with a gripper, according to an embodiment. 11 and 12 illustrate a stamping station 1100 with a gripper, according to an embodiment. 13A and 13B illustrate a cylindrical ring punctured in a stamping station, according to an embodiment. 14A and 14B illustrate a punctured ring with a circumference that varies along axial dimensions, according to certain embodiments. FIG. 15 illustrates an expandable core with a rounded die compartment, according to an embodiment. 16A and 16B illustrate another punctured ring with a circumference that varies in axial dimensions, according to one embodiment. FIG. 17 shows an expandable core with a conical die compartment, according to an embodiment. FIG. 18 illustrates a ring with a cylindrical wall and an edge extending from the cylindrical wall, according to an embodiment. FIG. 19 illustrates an alternative configuration with a hole punctured in a radial wall by a stamping station according to an embodiment. FIG. 20 illustrates another stamping system according to one embodiment. FIG. 21 is a flowchart of a method for puncturing a radial wall in a thru-operated manner according to an embodiment. FIG. 22 is a flowchart of a method for performing a plurality of through-actuated puncture operations on an object having a radial wall according to an embodiment. FIG. 23 is a flow chart of a method for forming an object having a radial wall with holes according to an embodiment. FIG. 24 illustrates a speed ring according to an embodiment. FIG. 25 illustrates a bearing cage according to an embodiment.

(Detailed description of the embodiment)
FIG. 1 illustrates one through-actuated stamping station 100. The stamping station 100 is configured to puncture one or more holes in a ring-shaped component having a radial wall. The stamping station 100 may form several holes in the radial wall in a single punching operation. The stamping station 100 includes an expandable core 120 that holds a component 190 with a radial wall 192. When expanded, the core 120 applies an outward pressure 122 in the radial direction to the surface 196 facing inward in the radial direction of the radial wall 192.

In the present specification, "inward in the radial direction" refers to a direction substantially toward the axis 198 of the component 190, and "outward in the radial direction" refers to a direction substantially away from the axis 198. In one embodiment, component 190 has cylindrical symmetry and axis 198 is a cylindrical axis. In another embodiment, the intended use of part 190 (when finished) involves rotation about an inner axis of rotation of the radial wall 192, with axis 198 being an axis of rotation. The radial inward and radial outward directions may deviate from being exactly perpendicular to axis 198 without departing from the scope of the specification. For example, with respect to a cylindrical embodiment of the radial wall 192, the radial inward and radial outward directions may be up to 10 or 45 degrees from a vertical incident on the radial wall 192, and so on. It may deviate from the minute.

The stamping station 100 further includes at least one through-actuated punching machine 110 that moves along the radial inward direction 150. Each punching machine 110 thereby punctures a separate hole 194 within the radial wall 192. Each punching machine 110 moves to perform a puncture operation in a single through-actuated movement. An embodiment of a stamping station 100 equipped with a plurality of punching machines 110 can simultaneously form a plurality of holes 194 in a radial wall 192, the plurality of holes 194 being different (relative to the axis 198). It may be located in the azimuth position.

The expandable core 120 allows a tight fit of the inwardly facing surface 196 of the component 190 onto the core 120. In an exemplary operation, component 190 is installed in a stamping station around the expandable core 120, which is sized smaller than the surface 196 on which the expandable core faces inward. The expandable core 120 is subsequently expanded to form a tight fit with the inwardly facing surface 196. This tight fit anchors the component 190 within the stamping station 100. In addition, the expandable core 120 may form and / or sizing the radial wall 192 to achieve the desired final shape and / or size by an outward pressure 122 in the radial direction. .. For example, the expandable core 120 may ensure that the surface 196 facing inward in the radial direction has a circular cross section at any axial position of the radial wall 192. Without departing from the scope of this specification, the shape and / or size of part 190 may be modified in later operation. In one embodiment, the radial outward pressure applied by the expandable core 120 improves the roundness of the radial wall 192. In another embodiment, the expandable core 120 slightly expands the radial wall 192 to achieve the final size. For a non-cylindrical part 190, for example a conical radial wall 192 or a radial wall 192 with several cylindrical compartments with different diameters, in the radial direction of the core 120 applying outward pressure in the radial direction. The outwardly facing surface may be shaped to match at least a portion of the shape (or desired final shape / size thereof) of the radially inwardly facing surface 196. In addition, the radial outward pressure applied by the core 120 during the puncture of the radial wall 192 can serve to prevent deformation of the radial wall 192 during the puncture operation. The radial outward pressure applied by the core 120 during the puncture of the radial wall 192 can also serve to prevent the formation of burrs in the hole 194 during the puncture operation.

In one embodiment, the stamping station 100 drives the drive ring 130 and the rotation of the drive ring 130 along approximately azimuth 140 (relative to axis 198) along the individual radial inward directions 150. Includes at least one through 112 that moves each punching machine 110. Each through 112 may be coupled with a drive device such as a servo drive that drives the rotation of the through 112.

2A and 2B illustrate one expandable core 200, including a plurality of die compartments 210. The die compartments 210 are arranged around the tapered plunger 220. 2A and 2B show the expandable core 200 and the tapered plunger 220, respectively, in perspective and cross-sectional side views, respectively. Both FIGS. 2A and 2B are best visible in the following description.

The expandable core 200 is an embodiment of the expandable core 120, which may be mounted in the stamping station 100 together with the tapered plunger 220. When mounted in the stamping system 100 during operation, the tapered plunger 220 is lowered, pushing the die compartment 210 radially outward from the shaft 298 along the individual directions 222, and radially outward. A directional pressure of 122 is applied. When mounted in the stamping station 100 and holding the component 190, the shaft 298 may coincide with the shaft 198.

In certain embodiments, one or more of the die compartments 210 receive a separate punching machine 110 after the punching machine 110 punctures through the radial wall 192 and / or is removed from the radial wall 192 by the punching machine 110. Form a receiver or chute 212 that is configured to receive the material punctured in. Such material may pass through the receiver / chute 212, as indicated by arrow 214.

3A and 3B illustrate a thru-actuated stamping station 300, which is an embodiment of the stamping station 100. FIG. 3A shows the initial configuration of the stamping station 300 after receiving the component 190. FIG. 3B shows a configuration of a stamping station 300 after puncturing the radial wall 192 of component 190. Both FIGS. 3A and 3B are best visible.

The stamping station 300 includes a drive ring 330, at least one punching machine 310, and a guide 360. The stamping station 300 also includes an expandable core 120 that can be implemented as an expandable core 200 with a tapered plunger 220. Each punching machine 310 is mounted on the punching machine main body 340, which is connected to the drive ring 330 via the lever 350. Without departing from the scope of the present specification, each punching machine main body 340 may have more than one punching machine 310 mounted therein. The guide 360 limits the movement of each punching machine body 340, and therefore each punching machine 310, to be inward in the radial direction or outward in the radial direction. Although not depicted in FIGS. 3A and 3B for clarity, the stamping station 300 may further include one or more through 112s for activating the drive ring 330.

The joint between the lever 350 and the punching machine body 340 allows the lever 350 to be pivoted around the pivot shaft 352. The joint between the lever 350 and the drive ring 230 allows the lever 350 to be pivoted around the pivot shaft 354. The pivot shafts 352 and 354 may be parallel to the shaft 198 (when the component 190 is mounted within the stamping station 300), respectively.

As shown in FIG. 3A, the component 190 is mounted on the expandable core 120, while (a) the drive ring 330 is in a different orientation position than the corresponding pivot axis 352 with each pivot axis 354. (B) The expandable core 120 is sized smaller than the radial wall 192. This ensures that the punching machine 310 is retracted away from the radial wall 192. The expandable core 120 is then expanded to rotate the drive ring 330 in a thru-actuated manner along the direction 140, as shown in FIG. 3B. In response to this rotation, each pivot shaft 354 is moved to a directional position closer to the directional position of the corresponding pivot shaft 352. This results in an inward movement in the radial direction of the corresponding punching machine body 340 within the guide 360 along the radial inward direction 150, and one or more mounted on the punching machine body 340. The radial wall 192 is punctured using a punching machine 310. In the embodiment shown in FIGS. 3A and 3B, each punching machine 310 is located in the most inward position in the radial direction when the lever 350 is parallel to the punching machine main body 340. In certain embodiments, the azimuth displacement of the drive ring 330 between FIGS. 3A and 3B is in the range of 5-20 degrees. Once the puncture is complete, the drive ring 330 may rotate back to the position shown in FIG. 3B. Alternatively, the drive ring 330 may rotate in the same directional 140 as from FIGS. 3A to 3B until each punching machine 310 is retracted from the radial wall 192.

FIG. 4 illustrates two examples 400 (1) and 400 (2) of one through-actuated stamping station 400 mounted within an exemplary stamping system 402. FIG. 5 is a top view of the stamping station 400. The stamping station 400 is an embodiment of the stamping station 100. Both FIGS. 4 and 5 are best viewed in the following description.

Each stamping station 400 includes an expandable core 520, which is an embodiment of an expandable core 200. Each stamping station 400 further includes a tapered plunger 525, which is an embodiment of the tapered plunger 220. Each stamping station 400 also includes at least one through 410 that operates one or more punching machines 510 and moves them along a radial inward direction 550. In addition, each stamping station 400 includes a drive ring 530. The thru 410 drives the rotation of the drive ring 530 along the substantially azimuth direction 540 (relative to the axis 198) and moves each punching machine 510 along the individual radial inward directions 550. Each thru 410 may be coupled to a drive device 412 such as a servo drive that drives the rotation of the thru 410. The stamping station 400 is an embodiment of the stamping station 300. The embodiment of the stamping station 400 illustrated in FIGS. 4 and 5 includes two thru 410s and a plurality of punching machines 510, whereas the stamping station 400 includes only a single thru 410 and more than two thru 410s. And / or may be configured with only a single punching machine 510.

The stamping system 402 may include one or more grippers 460 that grip the component 190 to move the component 190 to different positions within the stamping system 402. In one embodiment, the first gripper 460 is configured to install the component 190 in the stamping station 400 (1), and the second gripper 460 is from the stamping station 400 (1) to the stamping station 400 (2). The third gripper 460 is configured to extract the component 190 from the stamping station 400 (2).

Without departing from the scope of this specification, the stamping system 402 may include additional examples of the stamping station 400. The stamping system 402 may replace each of the one or more stamping stations 400 with another embodiment of the stamping station 100.

6 and 7 illustrate the stamping station 400 in more detail. FIG. 6 shows a cross-sectional view of the stamping station 400, the cut section of which coincides with the location of the shaft 198 when the component 190 is mounted within the stamping station 400. For clarification of the illustration, FIG. 6 shows a stamping station 400 in which the component 190 is not mounted. FIG. 7 shows a top view of the stamping station 400 (not including the thru 410).

The expandable core 520 has a plurality of die compartments 610. The die compartment 610 and the tapered plunger 525 collide at the tapered interface 612 such that the descent of the tapered plunger 525 pushes the die compartment 610 radially outward, thereby expanding the core 520. It fits.

Each punching machine 510 of the stamping station 400 is mounted on the punching machine main body 640. Each punching machine main body 640 is connected to a drive ring 530 via a lever 650. The joint between the lever 650 and the punching machine body 640 allows the lever 650 to be pivoted around the pivot shaft 652. The joint between the lever 650 and the drive ring 530 allows the lever 650 to be pivoted around the pivot shaft 654. The pivot shafts 652 and 654 may be parallel to the shaft 198 (when the component 190 is mounted within the stamping station 400), respectively. The stamping station 400 further includes a guide 660 (an embodiment with a guide 360) that limits the movement of each punching machine body 640 to a radial inward direction 550.

In certain embodiments, each punching machine 510 is associated with a chute 670 in the corresponding one of the die compartments 610. The chute 670 receives the material punched out from the radial wall 192 by the punching machine 510 and drops the material.

FIG. 8 illustrates one puncher assembly 800 with a single puncher 510. The punching machine assembly 800 may be mounted within the stamping station 400. The punching machine assembly 800 includes a punching machine body 640 and a lever 650, which are configured as discussed above with reference to FIGS. 6 and 7. The punching machine assembly further includes a mount 860 configured to connect the distal end of the lever 650 to the drive ring 530. The punching machine body 640 has a single punching machine 510 mounted on the proximal end of the punching machine body 640. As used herein, the terms "distal" and "proximal" are used to indicate a position or portion further away from the axis 198 of the component 190 and a position or a portion closer thereto when the component 190 is mounted in the stamping station, respectively. Refers to the part.

FIG. 9 illustrates one punching machine assembly 900 with two punching machines 510. The punching machine assembly 900 is similar to the punching machine assembly 800, except that it has two punching machines 510 mounted on the proximal end of the punching machine body 640. Without departing from the scope of this specification, the punching machine assembly 900 may have more than two punching machines 510 mounted on the near end of the punching machine body 640.

FIG. 10 illustrates an expandable core 1000 that includes a plurality of die compartments 1010. The expandable core 1000 is an embodiment with an expandable core 520, and the die compartment 1010 is an embodiment with a die compartment 610. Each die compartment 1010 that coincides with the location for puncture by the punching machine 510 forms a receiver 1070 for the punching machine 510. The receiver 1070 may continue through the die compartment 1010 to form an embodiment of chute 670.

11 and 12 illustrate one exemplary stamping station 1100 that combines a stamping station 400 with a gripper 460. FIG. 11 shows a cross-sectional side view of the stamping station 400. FIG. 12 shows an enlarged view of a part 1190 of the stamping station 1100. 11 and 12 are both best visible in the following description. In the embodiment shown in FIG. 12, the stamping station 1100 includes a drive device 1240 that controls the movement of the tapered plunger 525 and expands or contracts the expandable core 520.

Without departing from the scope of this specification, the stamping station 1100 may have more than one gripper 460. In one embodiment, the first gripper 460 is configured to install the component 190 in the stamping station 400, and the second gripper 460 is configured to extract the component 190 from the stamping station 400.

13A and 13B illustrate one cylindrical ring 1300 punctured within the stamping station 100. FIG. 13A shows the cylindrical ring 1300 in perspective view. FIG. 13B shows a cross-sectional view of the cylindrical ring 1300, the cross-section of which was obtained in a radial plane. 13A and 13B are both best visible in the following description. The cylindrical ring 1300 is a cylindrical wall 1310 with a plurality of holes 1320 formed therein by the stamping station 100. The cylindrical axis of the cylindrical ring 1300 coincides with axis 198. In one embodiment, the holes 1320 are equidistant in the directional direction (relative to axis 198). Although FIG. 13A shows the holes 1320 as being rectangular, the holes 1320 may have different shapes without departing from the scope of this specification. For example, the hole 1320 may be circular, polygonal with three or more sides, or more complex.

14A and 14B illustrate one punctured ring 1400 with a circumference that varies along axial dimensions. Ring 1400 is punctured within the stamping station 100. FIG. 14A shows the ring 1400 in perspective view. FIG. 14B shows a cross-sectional view of the ring 1400 whose cross-section was obtained in a radial plane. 14A and 14B are both best visible in the following description. Ring 1400 has a radial wall 1410 with a plurality of holes 1420 formed therein by the stamping station 100. Any cross section of the radial wall 1410 obtained in a plane orthogonal to axis 198 (except for the lost portion in hole 1420) is substantially circular. However, the diameter of the cross section varies along axis 198. In one embodiment, the holes 1420 are equidistant in the directional direction (relative to axis 198). FIG. 14A shows the hole 1420 as being rectangular, but the hole 1420 has a different shape as discussed above with reference to FIG. 13A without departing from the scope of the present specification. May be good. Also, without departing from the scope of this specification, the variation in diameter along axis 198 may differ from that shown in FIGS. 14A and 14B.

FIG. 15 illustrates one expandable core 1500 with a rounded die compartment 1510. The expandable core 1500 is an embodiment of an expandable core 200 configured to hold the ring 1400 during puncture within the stamping station 100. Each die compartment 1510 is ringed so that when the tapered plunger 220 pushes the die compartment 1510 radially outward, a tight fit is achieved between the die compartment 1510 and the radial wall 1410. It has a rounded radial outward facing surface 1512 that matches the shape of the radial wall 1410. One or more die compartments 1510 may form the receiver / chute 212. When the expandable core 1500 is extended with respect to the radial wall 1410, the surface 1512 facing outwardly in the radial direction is radial so that the final desired shape of the radial wall 1410 is achieved. It should be understood that the shape of the wall 1410 can be modified.

16A and 16B illustrate another punctured ring 1600 with a circumference that varies in axial dimensions. Ring 1600 is punctured within the stamping station 100. FIG. 16A shows the ring 1600 in perspective view. Ring 1600 is formed from a single component. FIG. 16B shows a cross-sectional view of the ring 1600 whose cross-section was obtained in a radial plane. 16A and 16B are both best visible in the following description. Ring 1600 has a conical radial wall 1610 and an edge 1612 extending inward from the conical radial wall toward axis 198. The conical radial wall 1610 has a plurality of holes 1620 formed therein by the stamping station 100. Any cross section of the conical radial wall 1610 obtained in a plane orthogonal to axis 198 (except for the lost portion in hole 1620) is substantially circular. However, the diameter of the cross section varies along axis 198. In certain embodiments, the holes 1620 are equidistant in the directional direction (relative to axis 198). FIG. 16A shows the hole 1620 as being rectangular, but the hole 1620 has a different shape as discussed above with reference to FIG. 13A without departing from the scope of the present specification. May be good. Also, without departing from the scope of this specification, the variation in diameter along axis 198 may differ from that shown in FIGS. 16A and 16B. For example, the diameter of the conical radial wall 1610 may decrease away from the margin 1612, or the conical radial wall 1610 is rounded similar to the radial wall 1410 of the ring 1400. It may be replaced, at least partially, by a wall. In the embodiments shown in FIGS. 16A and 16B, the edge 1612 is orthogonal to the axis 198. Alternatively, the edge 1612 may be at an oblique angle with respect to the axis 198.

FIG. 17 illustrates one expandable core 1700 with a conical die compartment 1710. The expandable core 1700 is an embodiment of an expandable core 200 configured to hold the ring 1600 during puncture within the stamping station 100. Each die compartment 1710 is ringed so that when the tapered plunger 220 pushes the die compartment 1710 radially outward, a tight fit is achieved between the die compartment 1710 and the radial wall 1610. It has an angled radial outward facing surface 1712 that matches the shape of the radial wall 1610. One or more die compartments 1710 may form the receiver / chute 212. When the expandable core 1700 is extended with respect to the radial wall 1610, the surface 1712 facing outwardly in the radial direction is radial so that the final desired shape of the radial wall 1610 is achieved. It should be understood that the shape of the wall 1610 can be modified.

FIG. 18 illustrates one ring 1800 with a cylindrical wall 1810 and an edge 1820 extending from the cylindrical wall 1810. Ring 1800 is formed from a single component. The edge 1820 is orthogonal to the axis 198. The ring 1800 may be installed in the stamping station 100 to puncture a hole in the cylindrical wall 1810.

For each embodiment discussed above with reference to FIGS. 13A-18, the stamping station 100 is an inwardly facing surface of a radial wall to be punctured (eg, wall 1310, 1410, 1610, or 1810). It may be configured with an expandable core having a radial outward facing surface that matches at least a portion of the.

FIG. 19 illustrates a perforated alternative configuration punctured into a radial wall by the stamping station 100. The ring 1910 has a radial wall 1912 with a plurality of holes 1914 that are not equidistantly spaced within the azimuth dimension 1916. Another ring 1920 has a radial wall 1922 with holes 1924 drilled in places not centered on the radial wall 1922 in axial dimensions. Yet another ring 1930 has a radial wall 1932 with a plurality of holes 1934 that are not of the same shape. It should be understood that each radial wall discussed with reference to FIGS. 1-18 may have holes due to one or more of the configurations shown in FIG.

FIG. 20 illustrates one exemplary stamping system 2000 in a top view (top of FIG. 20) and a side view (bottom of FIG. 20). The stamping system 2000 includes two examples 400 (1) and 400 (2) of the stamping station 400. The two stamping stations 400 (1) and 400 (2) may puncture different hole patterns. The stamping system 2000 receives the part at location 2010. When configured to handle a ring with a weld (such as when a ring is formed by forming a flat sheet into a roll), the gripper orients the part according to a predetermined orientation. Move to rotation station 2020. For rings that do not have welds, or if the orientation of the welds is not important, the stamping system 2000 may omit the rotary station 2020. The gripper then moves the component to the first stamping station 400 (1) for stamping one or more first holes. The gripper then moves the component to the second stamping station 400 (2) for stamping one or more second holes. The second hole may be formed in the same radial wall as the first hole. Alternatively, if the part contains more than one radial wall or radial wall compartment, the first and second holes are formed in separate first and second radial walls or wall compartments. You may. The stamping system 2000 may be configured to maintain the orientation of the weld through each station of the stamping system 2000.

Since the stamping system 2000 has two stamping stations 400, the stamping system 2000 is more than, for example, puncturing all holes by a single stamping 400 can result in ring deformation or can be supplied by a single stamping station 400. It may be possible to puncture more holes than a single stamping station 400 if it will require more power.

System 2000 may be configured to transfer the punctured ring to another machine that further modifies the shape of the ring. For example, the gripper may transfer the ring to a roll forming device to change the shape of the radial wall.

FIG. 21 is a flow chart of one exemplary method 2100 for puncturing a radial wall in a thru-actuated manner. Method 2100 may be implemented by the stamping station 100 as discussed above. In step 2110, method 2100 applies an outward pressure in the radial direction to a surface that faces inwardly in the radial direction of the radial wall. In one embodiment of step 2110, the expandable core 120 applies a radial outward pressure 122 to the radially inwardly facing surface 196 of the radial wall 192. Step 2110 may include one or more of steps 2112, 2114, 2116, and 2118. Optional step 2112 expands the core, eg, expandable core 120, and applies radial outward pressure, eg, radial outward pressure 122. Optional step 2114 achieves the final size and / or shape of the surface facing inward in the radial direction by the applied radial pressure. Optional step 2116 prevents burrs in the radial wall due to the applied radial outward pressure. Voluntary step 2118 prevents deformation of the radial wall due to the applied radial pressure.

In step 2120, method 2100 drives at least one slew, activates at least one punch, and at least one hole in the radial wall along a direction substantially opposite to the radial outward pressure. To puncture. Step 2120 may include one or both of steps 2122 and 2124. Step 2122 drives the thru and rotates the drive ring coupled to the thru and each punching machine to move each punching machine. In one embodiment of step 2122, the thru 112 rotates the drive ring 130 and moves the punching machine 110 inward in the radial direction along the direction 150. Step 2124 guides the movement of each punching machine along the radial inward direction and punctures the radial wall. In one embodiment of step 2124, the guide 360 guides the movement of one or more punching machine bodies 340. Steps 2122 and 2124 may be performed at the same time.

Method 2100 may maintain outward pressure in the radial direction of step 2110 while performing step 2120.

FIG. 22 is a flow chart of one exemplary method 2200 for performing a plurality of thru-actuated puncture movements on an object having a radial wall. Method 2200 is implemented by the stamping system 2000, for example, as discussed above with reference to FIG.

In step 2210, the stamping system receives an object with a radial wall. In one embodiment of step 2210, the stamping system 2000 receives component 190. In step 2230, method 2200 performs method 2100 at the first stamping station to puncture one or more first holes in the radial wall. In one embodiment of step 2230, the stamping station 400 (1) of the stamping system 2000 punctures one or more holes 194 in the radial wall 192. In step 2240, method 2200 performs method 2100 at the second stamping station to puncture one or more second holes in the radial wall. In one embodiment of step 2240, the stamping station 400 (2) of the stamping system 2000 punctures one or more additional holes 194 in the radial wall 192. In step 2250, method 2200 outputs an object with a punctured radial wall.

In one embodiment of Method 2200, the object is a welded ring. The welded ring may have a weld seam used to complete the roll formation of the ring from a flat sheet. In this embodiment, (a) step 2210 implements step 2212, which receives the welded ring, and (b) method 2200 further, for example, the weld seam is pierced in a subsequent step of method 2200. Includes step 2220 to orient the weld seam away from where it should be, (c) step 2230 implements step 2232 to maintain the orientation of the weld seam, and (d) step 2240 maintains the orientation of the weld seam. Step 2242 is implemented. In one embodiment of this embodiment of method 2200, the stamping system 2000 receives the part 190, the radial wall 192 has a weld seam parallel to the axis 198, and one or more grippers (gripper 460, etc.). ), Orient the part 190 and maintain that orientation so that the weld seam is away from any location to be punctured by the stamping station 400.

Method 2200 may omit step 2240 without departing from the scope of the specification.

FIG. 23 is a flow chart of one exemplary method 2300 for forming an object having a radial wall with holes. In certain embodiments, Method 2300 combines the advantages of rolling (eg, material savings) with Method 2100's efficient through-actuated puncture process.

In step 2310, method 2300 forms a ring with a radial wall. In one embodiment, step 2310 comprises forming a ring from a flat sheet into a roll. The process of forming this roll may produce a ring with weld seams. Step 2312 may include step 2314 forming a plurality of compartments along the axial dimensions of the ring, at least two of which compartments have different polar angles with respect to the axis of the ring. As used herein, "pole angle with respect to an axis" refers to the angle of a ring with respect to an axis in a planar cross section, including an axis equivalent to the pole angle of a spherical coordinate system (eg, axis 198). 14A, 14B, 16A, and 16B show examples of rings with compartments having different polar angles with respect to axis 198. In another embodiment, step 2310 comprises cutting the ring from the tube. Step 2316 may include step 2318 forming the cut ring into a roll so that it has a plurality of compartments along the axial dimensions of the ring, of which at least two of the compartments are of the ring. It has different polar angles with respect to the axis.

In step 2320, method 2300 performs method 2100 or method 2200 to puncture one or more holes in at least one radial wall of the ring.

Method 2300 may further include step 2330 modifying the shape of the punctured ring. Step 2330 may include step 2332 forming the punctured ring into a roll. In one embodiment of step 2330, the shape of the ring 190 is modified after puncture by the stamping system 2000 or stamping station 400.

FIG. 24 illustrates one exemplary speed ring 2400 punctured by the stamping station 100 according to method 2100. The speed ring 2400 has a cylindrical wall 2410 with a plurality of holes 2420 formed by the stamping station 100. The speed ring 2400 is similar to the cylindrical ring 1300. In one embodiment, the speed ring 2400 is rolled from a flat sheet and welded at the seams prior to puncturing the hole 2420 by the stamping station 100. In this embodiment, the stamping station 100 may maintain the orientation of the weld seams to ensure that the punching machine 110 does not pass through the weld seams. An exemplary weld seam 2450 is shown in FIG. Alternatively, the weld seam 2450 may be oriented such that the punching machine 110 passes through the weld seam 2450.

The speed ring is made of steel such as AISI low carbon steel and has (a) a diameter of 2472 in the range of 5-10 inches and (b) a radial wall thickness of 2470 in the range of 0.05 to 0.2 inches. Each hole 2420 has a height of 2474 in the range of 0.1 to 5.0 inches and a width in the range of 0.05 to 0.5 inches.

FIG. 25 illustrates one exemplary bearing cage 2500 punctured by the stamping station 100 according to method 2100. The bearing cage 2500 includes a radial wall 2510 and an edge 2520. The radial wall 2510 has a plurality of holes 2530 formed by the stamping station 100. The bearing cage 2500 is similar to the punctured ring 1600. Each of the holes 2530 may be adapted to a tapered roller. The bearing cage 2500 is made of a material similar to that of the speed ring 2400, or bears similar dimensions.

Combination of features

The features described above as well as those claimed below can be combined in various ways without departing from the scope of this specification. For example, a radial wall as described herein, or an aspect of one system or method for through-actuated puncture of a portion associated with a radial wall, is described herein as a radial wall, or. It should be understood that features of another system or method for through-actuated puncture of the part associated with the radial wall may be incorporated or replaced. The following examples illustrate non-limiting combinations of possible embodiments described above. It should be made clear that many other changes and modifications can be made to the systems and methods described herein without departing from the spirit and scope of the invention.

(A1) The thru-actuated stamping station has an expandable core configured to apply radial outward pressure to the surface of the radial wall facing inward in the radial direction and inward in the radial direction. It may include at least one thru-actuated punching machine for piercing individual holes in the radial wall along the orientation.

The stamping stations shown in (A2) and (A1) are further (a) a drive ring and (b) at least one punching machine holder, each of which is one or more of at least one through-acting punching machine. Use a punching machine holder to connect to the drive ring, (c) a guide to guide each punching machine holder towards the radial wall, and (d) a radial wall using each through-actuated punching machine. It may also include a first thru for rotating the drive ring to drive each punching machine holder along the guide so as to puncture.

(A3) In the stamping station shown in (A2), at least one or more of the punching machine holders may have exactly one punching machine mounted on the stamping machine holder.

(A4) At any of the stamping stations shown in (A2) and (A3), one or more of at least one punching machine holder has more than one punching machine mounted on it. You may have.

(A5) In any of the stamping stations shown in (A2) to (A4), each punching machine holder is (i) one or more individual of at least one through-actuated punching machine attached to it. The punching machine main body, the guide is a lever for connecting the punching machine main body and (ii) the punching machine main body to the drive ring, which is configured to guide the punching machine main body. The rotation allows the punching machine body and the lever to be pivoted with respect to the drive ring via a proximal joint that allows the lever to be pivoted relative to the punching machine body so that the punching machine body is moved along the guide. It may include a lever, which is coupled to both the drive ring and through a distal joint.

In the stamping stations shown in (A6) and (A5), each punching machine holder should install the individual punching machine body in the most inward position in the radial direction when the lever is parallel to the punching machine body. It may be configured in.

(A7) Any of the stamping stations shown in (A2) to (A6) may further include a second thru for cooperating with the first thru to rotate the drive ring.

(A8) In the stamping station shown in (A7), the first thru and the second thru may be coupled to both sides of the drive ring.

(A9) Any of the stamping stations shown in (A1) to (A8) may further include a tapered plunger capable of moving along the axial dimensions of the radial wall. The expandable core is such that when the tapered plunger is moved to interfacially contact the tapered die compartment at a larger diameter of the tapered plunger, the tapered die compartment moves outward in the radial direction. , May include a plurality of tapered die compartments arranged around a tapered plunger.

In the stamping stations shown in (A10) and (A9), the plurality of tapered die compartments are directed inward in the radial direction of the radial wall when the tapered plunger pushes the tapered die compartment radially outward. It may include a plurality of individual radial outward facing surfaces for applying outward pressure to the facing surface.

In the stamping stations shown in (A11) and (A10), the surface of the tapered die compartment facing outward in the radial direction is the final of the radial wall when the tapered die compartment applies an outward pressure in the radial direction. The final shape of the surface facing inward in the radial direction of the radial wall may be approximated to achieve the shape.

In the stamping station shown in (A12) and (A11), the final shape may be cylindrical or conical.

(A13) In any of the stamping stations shown in (A11) and (A12), the final shape may be characterized by a circular cross section at any axial position within the axial range of the radial wall. ..

(A14) In any of the stamping stations shown in (A9) to (A13), the tapered die compartment is configured to receive and drop material that is removed from the radial wall by the puncture. One or more shoots may be formed.

(A15) In any of the stamping stations shown in (A1) to (A14), at least one through-actuated punching machine is responsible for puncturing individual rectangular holes in a radial wall. It may include a punching machine formed into a plurality of rectangles.

(A16) At one of the stamping stations shown in (A1) to (A15), at least one through-actuated punching machine punctures a plurality of individual holes at equidistant azimuth positions on the radial wall. It may include a punching machine formed into a plurality of rectangles for the purpose.

(A17) Any of the stamping stations shown in (A1) to (A16) may be further mounted in a stamping system, including a second thru actuated stamping station, and the second thru actuated. The formula stamping station is (I) a second expandable core for holding the radial wall after piercing the radial wall in the thru-actuated stamping station and faces inward in the radial direction. A second expandable core configured to apply radial outward pressure to the surface and (II) at least one individual in the radial wall along the radial inward direction. Includes at least one second through-actuated punching machine for piercing the second hole or changing the shape of one or more of the at least one first hole.

The methods for (B1) piercing the radial wall are, at the same time, (a) applying an outward pressure in the radial direction to the surface of the radial wall facing inward in the radial direction and (b). ) It may include driving a thru, operating at least one punching machine, and piercing at least one hole in the radial wall along the direction opposite to the outward pressure in the radial direction.

(B2) In the method shown in (B1), the applying step may include expanding the core and applying an outward pressure in the radial direction.

(B3) In the method shown in (B2), the expanding step uses a tapered plunger to push a plurality of tapered die compartments, located inside a radial wall, outward in the radial direction. May include.

(B4) In any of the methods shown in (B1) to (B3), the step of application may include achieving the final shape of the surface facing inward in the radial direction.

In the method shown in (B5) and (B4), the step of application may further include preventing at least one of (a) burrs in the radial wall and (b) deformation of the radial wall.

(B6) In any of the methods shown in (B4) and (B5), the step to be achieved is to have a surface facing inward in the radial direction in a circular cross section at any axial position of the radial wall. May include achieving to have.

(B7) In any of the methods shown in (B4) to (B6), the step to be achieved is to achieve that the surface facing inward in the radial direction is cylindrical or conical. It may be included.

(B8) In any of the methods shown in (B1) to (B7), the driving step (i) drives the thru to move each punching machine and combines it with the thru and each punching machine. It may include rotating the drive ring to be driven and (ii) guiding the movement of each punching machine along a radial inward direction to puncture the radial wall.

In the method shown in (B9) and (B8), the driving step is to move a plurality of punching machines coupled to the driving ring, and to move the punching machines inward along individual radial directions, respectively. May include puncturing multiple holes in the radial wall.

The methods shown in (B10) and (B9) are to (I) directionally shift the position of each distal end of at least one lever coupled to the drive ring in the driving step and (II). In the guiding step, (1) one or more individual of at least one punching machine connected to and (2) mounted on the individual proximal end of at least one lever. It may include inducing inward movement in each radial direction of at least one punching machine body having a thing and puncturing at least one hole.

(B11) Any of the methods shown in (B1) to (B10) involves performing the applying and driving steps within the first stamping station and puncturing at least one hole in the radial wall. And perform the steps of applying and driving within the second stamping station to puncture at least one second hole in the radial wall, or one or more shapes of at least one first hole. May include changing.

(C1) A method for forming an object with a radial wall with a hole is to form a ring with a radial wall and at least within the radial wall using at least one through-actuated punching machine. It may include puncturing one hole.

(C2) The method shown in (C1) may further include modifying the shape of the ring after the puncturing step.

(C3) In the method shown in (C2), the modifying step may include forming the ring into a roll.

(C4) In any of the methods shown in (C1) to (C3), the piercing step exerts a radial outward pressure on the surface of the radial wall facing inward in the radial direction. Includes applying and driving through, operating at least one punching machine, and piercing at least one hole in the radial wall along the direction opposite to the outward pressure in the radial direction. But it may be.

(C5) In the method shown in (C4), the step of application may include achieving the final shape of the radial wall.

(C6) In any of the methods shown in (C4) and (C5), the step of application is further at least one of (a) burrs in the radial wall and (b) deformation of the radial wall. May include preventing.

(C7) In any of the methods shown in (C1) to (C6), the forming step may include forming a flat sheet into a ring in a roll.

In the method shown in (C8) and (C7), the step of forming the roll shape may further include forming a plurality of divisions along the axial dimension of the ring into the ring shape. At least two have different polar angles with respect to the axis of the ring.

(C9) In any of the methods shown in (C1) to (C6), the forming step may include cutting the ring from the tube.

(C10) In any of the methods shown in (C1) to (C9), the forming step may include forming a ring such that the radial wall is cylindrical or conical.

(C11) In any of the methods shown in (C1) to (C10), the forming step is to form a ring such that the cross section of the radial wall at any axial position is circular. May include.

Modifications can be made to the systems and methods described above without departing from the scope of this specification. It should be noted, therefore, that the matters contained in the above description and shown in the accompanying drawings should be construed as exemplary and not in a limiting sense. The following claims cover the general and specific features described herein, as well as the full description of the scope of the system and methods, which may be said to be in between, as a matter of wording. Is intended.

Claims (36)

It is a through-actuated stamping station
With an expandable core configured to apply radial outward pressure to the surface of the radial wall facing inward in the radial direction.
With at least one through-actuated punching machine for puncturing individual holes in the radial wall along the radial inward direction .
With the drive ring
A punching machine holder and a punching machine holder, each of which connects one or more of the at least one through-actuated punching machine to the drive ring.
A guide for guiding each punching machine holder toward the radial wall, and
It comprises a first thru for rotating the drive ring to drive each puncher holder along the guide so as to puncture the radial wall with each thru actuated puncher . Stamping station. The stamping station according to claim 1 , wherein one or more of the at least one punching machine holder strictly has one punching machine mounted on the punching machine holder. The stamping station according to claim 1 , wherein one or more of the at least one punching machine holder has more than one punching machine mounted on the punching machine holder. Each punching machine holder is
A punching machine body having one or more of the individual one or more of the at least one through-acting punching machine attached thereto, wherein the guide is configured to guide the punching machine body. When,
A lever that connects the punching machine main body to the drive ring, and the lever (a) with respect to the punching machine main body so that the rotation of the drive ring moves the punching machine main body along the guide. To the drive ring via a proximal joint that allows the lever to pivot, and (b) a distal joint that allows the lever to pivot with respect to the drive ring. The stamping station of claim 1 , wherein the stamping station is coupled with a lever. Each die cutter holder, the lever is, when the punching machine is parallel to the body, the formed separate punching machine body so as to set up the most inward position in the radial direction, according to claim 4 Stamping station. Further comprising a second through for cooperating with the first through to rotate the drive ring, stamping station according to claim 1. The stamping station according to claim 6 , wherein the first through and the second through are coupled to both sides of the drive ring. Further provided with a tapered plunger capable of moving along the axial dimensions of the radial wall.
The expandable core is moved so that the tapered plunger is interfacially contacted with the tapered die compartment at a larger diameter of the tapered plunger so that the tapered die compartment is radially outwardly outward. The stamping station of claim 1, comprising a plurality of tapered die compartments arranged around the tapered plunger so as to move. The plurality of tapered die compartments are such that when the tapered plunger pushes the tapered die compartment outward in the radial direction, the tapered die compartment faces the surface facing inward in the radial direction of the radial wall. 8. The stamping station of claim 8, comprising a plurality of individual radial outward facing surfaces for applying pressure. The surface of the tapered die compartment facing outward in the radial direction has the radius so that when the tapered die compartment applies outward pressure in the radial direction, the final shape of the radial wall is achieved. The stamping station according to claim 9 , which approximates the final shape of a surface facing inward in the radial direction of the directional wall. The stamping station according to claim 10 , wherein the final shape is cylindrical or conical. 10. The stamping station of claim 10 , wherein the final shape is characterized by a circular cross section at any axial position within the axial range of the radial wall. The stamping station of claim 8 , wherein the tapered die compartment forms one or more chutes configured to receive and drop material removed from the radial wall by the puncture. The stamping station according to claim 1, wherein the at least one through-actuated punching machine includes a plurality of rectangular punching machines for puncturing individual rectangular holes in the radial wall. .. The first aspect of the invention, wherein the at least one through-actuated punching machine includes a plurality of rectangular punching machines for puncturing individual plurality of holes at equidistant azimuth positions of the radial wall. Stamping station. After puncturing the radial wall in the thru-actuated stamping station, the second expandable core for holding the radial wall is the radial direction. With a second expandable core configured to apply radial outward pressure to the inwardly facing surface.
To puncture at least one individual second hole in the radial wall or reshape one or more of the at least one first hole along a radial inward direction. The stamping station of claim 1, further comprising a second through-actuated stamping station, comprising at least one second through-actuated punching machine. A method for puncturing a radial wall, and at the same time
Applying an outward pressure in the radial direction to the surface of the radial wall facing inward in the radial direction and
Drives through, actuates at least one punching machine, the radially along the direction opposite to the outward pressure, see containing and puncturing at least one hole in the radially inner wall,
The driving is
Driving the thru to move each punching machine and rotating the thru and the drive ring coupled to each punching machine.
To guide the movement of each punching machine along the radial inward direction and puncture the radial wall.
Including methods. 17. The method of claim 17, wherein the applying step comprises expanding the core and applying an outward pressure in the radial direction. 18. The method of claim 18 , wherein the expanding step uses a tapered plunger to push a plurality of tapered die compartments, located inside the radial wall, radially outward. .. 17. The method of claim 17, wherein the applying step comprises achieving the final shape of the surface facing inward in the radial direction. 20. The method of claim 20, wherein the applied step further comprises preventing at least one of (a) burrs in the radial wall and (b) deformation of the radial wall. 20. The method of claim 20, wherein the step to be achieved comprises achieving that the surface facing inward in the radial direction has a circular cross section at any axial position of the radial wall. 20. The method of claim 20, wherein the step to be achieved comprises achieving that the surface facing inward in the radial direction is cylindrical or conical. The driving step
Moving a plurality of punching machines coupled to the drive ring
17. The method of claim 17, comprising guiding each of the punching machines along individual radial inward directions to puncture a plurality of holes in the radial wall. In the driving step, directionally shifting the position of each distal end of at least one lever coupled to the driving ring.
In the guiding step, (a) one or more of the at least one punching machine connected to, and (b) mounted on an individual proximal end of the at least one lever. Inducing inward movement in each radial direction of at least one punching machine body having an individual to puncture the at least one hole.
17. The method of claim 17. Performing the application and driving steps within the first stamping station to puncture at least one hole in the radial wall.
Performing the application and driving steps within the second stamping station to puncture at least one second hole in the radial wall, or one or more of the at least one first hole. 17. The method of claim 17, comprising changing the shape. A method for forming an object with a radial wall with holes,
Forming a ring with a radial wall and
Puncture of at least one hole in the radial wall using at least one through-actuated punching machine .
A method comprising modifying the shape of the ring after the puncturing step. 27. The method of claim 27 , wherein the modifying step comprises forming the ring into a roll. The puncturing step is
Applying an outward pressure in the radial direction to the surface of the radial wall facing inward in the radial direction and
Claims include driving a thru, operating at least one punching machine, and puncturing at least one hole in the radial wall along the direction opposite to the radial outward pressure. 27 . 29. The method of claim 29 , wherein the applying step comprises achieving the final shape of the radial wall. 30. The method of claim 30, wherein the applied step further comprises preventing at least one of (a) burrs in the radial wall and (b) deformation of the radial wall. 27. The method of claim 27 , wherein the forming step comprises forming a flat sheet into a ring in a roll. A method for forming an object with a radial wall with holes,
And forming a ring with a radial wall, that said forming comprises forming a flat sheet into a roll in a ring, forming the rolled further axial direction of the ring It comprises forming a plurality of dimensional compartments in a roll on the ring, at least two of the compartments having different polar angles with respect to the axis of the ring .
To puncture at least one hole in the radial wall using at least one through-actuated punching machine.
Including methods. 27. The method of claim 27 , wherein the forming step comprises cutting the ring from a tube. 27. The method of claim 27 , wherein the forming step comprises forming the ring such that the radial wall is cylindrical or conical. 27. The method of claim 27 , wherein the forming step comprises forming the ring such that the cross section of the radial wall at any axial position is circular.

Images